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古细菌tRNA合成酶的编辑结构域。

A domain for editing by an archaebacterial tRNA synthetase.

作者信息

Beebe Kirk, Merriman Eve, Ribas De Pouplana Lluis, Schimmel Paul

机构信息

The Skaggs Institute for Chemical Biology, The Scripps Research Institute, Beckman Center, BCC379, 10550 North Torrey Pines Road, La Jolla, CA 92037, USA.

出版信息

Proc Natl Acad Sci U S A. 2004 Apr 20;101(16):5958-63. doi: 10.1073/pnas.0401530101. Epub 2004 Apr 12.

DOI:10.1073/pnas.0401530101
PMID:15079065
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC395905/
Abstract

The rules of the genetic code are established by aminoacylations of transfer RNAs by aminoacyl tRNA synthetases. New codon assignments, and the introduction of new kinds of amino acids, are blocked by vigorous tRNA-dependent editing reactions occurring at hydrolytic sites embedded within specialized domains in the synthetases. For some synthetases, these domains were present at the time of the last common ancestor and were fixed in evolution through all three of the kingdoms of life. Significantly, a well characterized domain for editing found in bacterial and eukaryotic threonyl- and all alanyl-tRNA synthetases is missing from archaebacterial threonine enzymes. Here we show that the archaebacterial Methanosarcina mazei ThrRS efficiently misactivates serine, but does not fuse serine to tRNA. Consistent with this observation, the enzyme cleared serine that was linked to threonine-specific tRNAs. M. mazei and most other archaebacterial ThrRSs have a domain, N2(A), fused to the N terminus and not found in bacterial or eukaryotic orthologs. Mutations at conserved residues in this domain led to an inability to clear threonine-specific tRNA mischarged with serine. Thus, these results demonstrate a domain for editing that is distinct from all others, is restricted to just one branch of the tree of life, and was most likely added to archaebacterial ThrRSs after the eukaryote/archaebacteria split.

摘要

遗传密码的规则是由氨酰tRNA合成酶对转运RNA进行氨酰化作用而确立的。新的密码子分配以及新种类氨基酸的引入,会被发生在合成酶特定结构域内水解位点的、活跃的依赖tRNA的编辑反应所阻断。对于某些合成酶而言,这些结构域在最后的共同祖先时期就已存在,并在生命的三个王国的进化过程中固定下来。值得注意的是,古细菌苏氨酰-tRNA合成酶中缺少在细菌和真核生物的苏氨酰-和所有丙氨酰-tRNA合成酶中发现的一个特征明确的编辑结构域。在这里我们表明,古细菌马氏甲烷八叠球菌苏氨酰-tRNA合成酶(ThrRS)能有效地错误激活丝氨酸,但不会将丝氨酸连接到tRNA上。与这一观察结果一致,该酶能清除与苏氨酸特异性tRNA相连的丝氨酸。马氏甲烷八叠球菌和大多数其他古细菌的ThrRS在N端融合有一个结构域N2(A),而在细菌或真核生物的直系同源物中未发现。该结构域中保守残基的突变导致无法清除被丝氨酸错误充电的苏氨酸特异性tRNA。因此,这些结果证明了一个与所有其他结构域不同的编辑结构域,它仅限于生命树的一个分支,并且很可能是在真核生物/古细菌分化之后添加到古细菌ThrRS中的。

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